Collagen synthesis is required for ascorbic acid-enhanced differentiation of mouse embryonic stem cells into cardiomyocytes

Ascorbic acid has been reported to promote the differentiation of embryonic stem (ES) cells into cardiomyocytes; however, the specific functions of ascorbic acid have not been defined. A stable form of ascorbic acid, namely, l-ascorbic acid 2-phosphate (A2-P), significantly enhanced cardiac differentiation; this was assessed by spontaneous beating of cardiomyocytes and expression of cardiac-specific markers obtained from mouse ES cells. This effect of ascorbic acid was observed only when A2-P was present during the early phase of differentiation. Treatment with two types of collagen synthesis inhibitors, l-2-azetidine carboxylic acid and cis-4-hydroxy-d-proline, significantly inhibited the A2-P-enhanced cardiac differentiation, whereas treatment with the antioxidant N-acetyl cysteine showed no effect. These findings demonstrated that ascorbic acid enhances differentiation of ES cells into cardiomyocytes through collagen synthesis and suggest its potential in the modification of cardiac differentiation of ES cells.     

DNA methyltransferase inhibition induces mouse embryonic stem cell differentiation into endothelial cells

Understanding endothelial cell (EC) differentiation is a step forward in tissue engineering, controlling angiogenesis, and endothelial dysfunction. We hypothesized that epigenetic activation of EC lineage specification genes is an important mediator of embryonic stem cell (ESC) differentiation into EC. Mouse ESC was differentiated by removing leukemia inhibitory factor (LIF) from the maintenance media in the presence or absence of the specific DNA methyltransferase (DNMT) inhibitor 5′-aza-2′-deoxycytidine (aza-dC). Expression of EC specification and marker genes was monitored by quantitative PCR, western, immunocytochemistry, and flow cytometry. Functionality of differentiated EC was assessed by angiogenesis assay. The methylation status in the proximal promoter CpGs of the mediators of EC differentiation VEGF-A, BMP4, and EPAS-1 as well as of the mature EC marker VE-cadherin was determined by bisulfite sequencing. ESC differentiation resulted in repression of OCT4 expression in both the absence and presence of aza-dC treatment. However, significant increase in angiogenesis and expression of the mediators of EC differentiation and EC-specific genes was only observed in aza-dC-treated cells. The DNMT inhibition-mediated increase in EC specification and marker gene expression was not associated with demethylation of these genes. These studies suggest that DNMT inhibition is an efficient inducer of EC differentiation from ESC.     

The SHB adapter protein is required for normal maturation of mesoderm during in vitro differentiation of embryonic stem cells

Definitive mesoderm arises from a bipotent mesendodermal population, and to study processes controlling its development at this stage, embryonic stem (ES) cells can be employed. SHB (Src homology 2 protein in beta-cells) is an adapter protein previously found to be involved in ES cell differentiation to mesoderm. To further study the role of SHB in this context, we have established ES cell lines deficient for one (SHB+/-) or both SHB alleles (SHB-/-). Differentiating embryoid bodies (EBs) derived from these ES cell lines were used for gene expression analysis. Alternatively, EBs were stained for the blood vessel marker CD31. For hematopoietic differentiation, EBs were differentiated in methylcellulose. SHB-/- EBs exhibited delayed down-regulation of the early mesodermal marker Brachyury. Later mesodermal markers relatively specific for the hematopoietic, vascular, and cardiac lineages were expressed at lower levels on day 6 or 8 of differentiation in EBs lacking SHB. The expression of vascular endothelial growth factor receptor-2 and fibroblast growth factor receptor-1 was also reduced in SHB-/- EBs. SHB-/- EBs demonstrated impaired blood vessel formation after vascular endothelial growth factor stimulation. In addition, the SHB-/- ES cells formed fewer blood cell colonies than SHB+/+ ES cells. It is concluded that SHB is required for appropriate hematopoietic and vascular differentiation and that delayed down-regulation of Brachyury expression may play a role in this context.     

Involvement of Ras in extraembryonic endoderm differentiation of embryonic stem cells

Embryonic stem (ES) cells, derived from the inner cell mass of blastocyst can differentiate into multiple cell lineages. In this study, we examined the possible involvement of Ras in ES cell differentiation. We found that Ras was activated upon formation of embryoid bodies (EBs), an initial step in ES cell differentiation. When expressed during EB differentiation, a dominant-negative mutant of Ras suppressed induction of marker genes for extraembryonic endoderm differentiation, including GATA-4, GATA-6, alpha-fetoprotein, and hepatocyte nuclear factor 3beta, while an activated mutant promoted their induction. Expression of a Ras mutant that selectively activates the Raf/MEK/Erk pathway also enhanced induction of extraembryonic endoderm markers, and treatment with a MEK inhibitor resulted in their decreased expression. In addition, Ras stimulated downregulation of Nanog, a suppressor of endoderm differentiation in ES cells. These data suggest that Ras activation during EB differentiation plays a crucial role in initiation of extraembryonic endoderm differentiation.     

Glutathione peroxidase-1 is required for self-renewal of murine embryonic stem cells

Embryonic stem (ES) cells are pluripotent cells that are capable of giving rise to any type of cells in the body and possess unlimited self-renewal potential. However, the exact regulatory mechanisms that govern the self-renewal ability of ES cells remain elusive. To understand the immediate early events during ES cell differentiation, we performed a proteomics study and analyzed the proteomic difference in murine ES cells before and after a 6-h spontaneous differentiation. We found that the expression level of glutathione peroxidase-1 (GPx-1), an antioxidant enzyme, is dramatically decreased upon the differentiation. Both knockdown of GPx-1 expression with shRNA and inhibiting GPx-1 activity by inhibitor led to the differentiation of ES cells. Furthermore, we showed that during early differentiation, the quick degradation of GPx-1 was mediated by proteasome. Thus, our data indicated that GPx-1 is a key regulator of self-renewal of murine embryonic stem cells.     

Dynamics of gene expression during bone matrix formation in osteogenic cultures derived from human embryonic stem cells in vitro

Characterization of directed differentiation protocols is a prerequisite for understanding embryonic stem cell behavior, as they represent an important source for cell-based regenerative therapies. Studies have investigated the osteogenic potential of human embryonic stem cells (HESCs), building upon those using pre-osteoblastic cells, however no consensus exists as to whether differentiating HESCs behave in a similar manner to the traditionally used osteoblastic progenitors. Thus, the aim of the current investigation was to define the gene expression pattern of osteoblastic differentiating HESCs, treated with ascorbic acid phosphate, β-glycerophosphate and dexamethasone over a 25 day period. Characterization of the gene expression dynamics revealed a phasic pattern of bone-associated protein synthesis. Collagen type I and osteopontin were initially expressed in proliferating immature cells, whereas osterix was up-regulated at the end of active cellular proliferation. Subsequently, mineralization-associated proteins, bone sialoprotein and osteocalcin were detected. In light of this dynamic expression pattern, we concluded that two distinguishable phases occurred during osteogenic HESC differentiation; first, cellular proliferation and secretion of a pre-maturational matrix, and second the appearance of osteoprogenitors with characteristic extracellular matrix synthesis. Establishment of this model provided the foundation of a time-frame for the additional supplementation with growth factors, BMP2 and VEGF. BMP2 induced the expression of principle osteogenic factors, such as osterix, bone sialoprotein and osteocalcin, whereas VEGF had the converse effect on the gene expression pattern.     

Culturing and differentiation of murine embryonic stem cells in a three-dimensional fibrous matrix

Embryonic stem (ES) cells have indefinite self-renewal ability and pluripotency, and can provide a novel cell source for tissue engineering applications. In this study, a murine CCE ES cell line was used to derive hematopoietic cells in a 3-D fibrous matrix. The 3-D matrix was found to maintain the phenotypes of undifferentiated ES cells as indicated by alkaline phosphatase (ALP) activity and stage specific embryonic antigen-1 (SSEA-1) expression. In hematopoietic differentiation, cells from 3-D culture exhibited similar cell cycle distribution and SSEA-1 expression to those in the initial cell population. The Oct-4 expression was significantly down-regulated, which indicated the occurrence of differentiation, although the level was slightly higher than that in Petri dish culture. The expression of c-kit, cell surface marker for hematopoietic progenitor, was higher in the 3-D culture, suggesting a better-directed hematopoietic differentiation. Cells in the 3-D matrix tended to form large aggregates associated with fibers. For large-scale processes, a perfusion bioreactor can be used for both maintenance and differentiation cultures. As compared to the static culture, a higher growth rate and final cell density were resulted from the perfusion bioreactor due to better control of the reactor environment. At the same time, the differentiation capacity of ES cells was preserved in the perfusion culture. The ES cell culture in the fibrous matrix thus can be used as a 3-D model system to study effects of extracellular environment and associated physico-chemical parameters on ES cell maintenance and differentiation.     

In vitro differentiation of murine embryonic stem cells into keratinocyte-like cells

Embryonic stem (ES) cells are omnipotent; they can differentiate into every cell type of the body. The development of culture conditions that allow their differentiation has made it conceivable to produce large numbers of cells with lineage-specific characteristics in vitro. Here, we describe a method by which murine ES cells can be differentiated into cells with characteristics of epidermal keratinocytes. Keratinocyte-like cells were isolated from embryoid bodies and grown in culture. Potential applications of this method are the in vitro differentiation of cells of interest from ES cells of mice with lethal phenotypes during embryonic development and the production of genetically modified epidermal keratinocytes that could be used as temporary wound dressing or as carriers of genes of interest in gene therapeutic treatments.     

Generation of insulin-expressing cells from mouse embryonic stem cells

The therapeutic potential of transplantation of insulin-secreting pancreatic beta-cells has stimulated interest in using pluripotent embryonic stem (ES) cells as a starting material from which to generate insulin secreting cells in vitro. Mature beta-cells are endodermal in origin so most reported differentiation protocols rely on the identification of endoderm-specific markers. However, endoderm development is an early event in embryogenesis that produces cells destined for the gut and associated organs in the embryo, and for the development of extra-embryonic structures such as the yolk sac. We have demonstrated that mouse ES cells readily differentiate into extra-embryonic endoderm in vitro, and that these cell populations express the insulin gene and other functional elements associated with beta-cells. We suggest that the insulin-expressing cells generated in this and other studies are not authentic pancreatic beta-cells, but may be of extra-embryonic endodermal origin.     

Comparative proteomic analysis of mouse embryonic stem cells and neonatal-derived cardiomyocytes

Pluripotent embryonic stem cells (ESCs) spontaneously differentiate via embryo-like aggregates into cardiomyocytes. A thorough understanding of the molecular conditions in ESCs is necessary before other potential applications of these cells such as cell therapy can be materialized. We applied two dimensional electrophoresis to analyze and compare the proteome profiling of spontaneous mouse ESC-derived cardiomyocytes (ESC-DCs), undifferentiated mouse ESCs, and neonatal-derived cardiomyocytes (N-DCs). Ninety-five percent of the proteins detected on the ESC-DCs and N-DCs could be precisely paired with one other, whereas only twenty percent of the ESC proteins could be reliably matched with those on the ESC-DCs and N-DCSs, suggesting a striking similarity between them. Having identified sixty proteins in the said three cell types, we sought to provide possible explanations for their differential expression patterns and discuss their relevance to cell biology. This study provides a new insight into the gene expression pattern of differentiated cardiomyocytes and is further evidence for a close relation between ESC-DCs and N-DCSs.     

组蛋白修饰对胚胎干细胞分化过程[]的调控机制

选用人类胚胎干细胞系和由人类胚胎干细胞系分化来的神经干细胞系为研究对象,分析组蛋白修饰对胚胎干细胞分化过程的调控作用。得到了两种细胞系差异表达基因转录起始位点侧翼区域内八种组蛋白修饰的分布模式,以及组蛋白修饰功能簇。研究表明在两类细胞系中,八种组蛋白修饰谱分布模式一致,且呈现两种分布类型; H3K27ac,H3K4me3和H3K9ac组成的功能簇是保守的;H3K27me3,H3K36me3和H3K79me1组成的功能簇以及H3K9me3和H3K27me3组成的功能簇在胚胎干细胞向神经干细胞分化的过程中消失。结果揭示了组蛋白修饰对胚胎干细胞系向神经干细胞系分化过程的部分调控机制,为该分化过程分子调控机制的研究提供部分重要的理论基础。     

In vitro differentiation of mouse embryonic stem cells after activation by retinoic acid

Embryonic stem (ES) cells are pluripotent cells isolated from the inner cell mass of blastocysts. ES cells are able to differentiate into the three primitive layers (endoderm, mesoderm, and ectoderm) of the organism, including the germline. In recent reports mouse ES cells have been successfully applied in the treatment of spinal cord injury, hereditary myelin disorder of the central nervous system, and diabetes mellitus. In this study, we investigated the induction of mouse ES cell differentiation, using culture of embryoid bodies (EBs) into the diverse tissues. EBs were formed by culturing ES cells (129/SV strain) in DMEM supplemented with 10% FBS, in the absence of feeder cells and leukemia inhibitory factor (LF). EBs were induced to differentiate by treatment with retinoic acid (RA). In control medium (non-RA medium) beating muscles, blood vessels, hemocytes, and cartilages were frequently observed in EBs. Moreover, when EBs were cultured in medium including RA (5 x 10(-8) M, and 5 x 10(-9) M), differentiation of the optic vesicle, lens, retina, and neural groove was observed. In this study we demonstrated that an efficient system for inducing the differentiation of ES cells using EBs.     

Ghrelin promotes the differentiation of human embryonic stem cells in infarcted cardiac microenvironment

Ghrelin is broadly expressed in myocardial tissues, where it exerts different functions. It also has been found to have a wide variety of biological functions on cell differentiation and tissue development. The aim of this study was to investigate the effect of ghrelin on human embryonic stem cell (hESC) differentiation in infarcted cardiac microenvironment. The hESCs grown on feeder layers expressed several pluripotential markers including alkaline phosphatase (AKP). Four weeks after transplantation into rat infarcted hearts, the hESCs and their progeny cells survived and formed intracardiac grafts were 54.7% and 19.6% respectively in ghrelin- and phosphate-buffered saline (PBS)-treated groups. Double immunostaining with anti-human Sox9 and anti-HNA or anti-human fetal liver kinase-1 (Flk1) and anti β-tubulin showed that the human grafts were in development. However, double positive stains were only found in the ghrelin-treated group. In addition, the hESC injection protocol was insufficient to restore heart function of the acute myocardial infarction model. Our study, therefore, provides a new insight of ghrelin on promoting hESC survival and differentiation in rat infarcted cardiac microenvironment. This may give a clue for therapy for myocardial infarction by hESCs or progeny cells.